EP0482683A1 - Method and apparatus for separating a flow of bulk material into fractions of different grain size - Google Patents

Abstract

A flow of bulk material is separated into fractions of different grain size, a material cushion (4) is built up as a material disperser (1) on a base (2) with a convexly arcuate throw-off edge (3) from the throw-off edge (3) at the escarpment angle of the material, the surface of which cushion forms a material dispersing surface (5), the trajectory parabola of the freely falling flow (7) of bulk material striking the material dispersing surface (5), a saddle-shaped divider (8) - consisting of a base (10) with a convexly arcuate front (11) and a concavely arcuate rear throw-off edge (12) and a material cushion (13) which is built up from the throw-off edges (11, 12) at the escarpment angle of the material with a comb (14) which runs parallel to the throw-off edges (11, 12) - being arranged in the freely falling, dispersed material flow (9) in such a way that a coarser fraction slides down to the convex throw-off edge (11) on the front side of the material cushion and is widened and thrown off and a finer fraction slides down towards the concave throw-off edge (12) on the rear side of the material cushion and is thrown off. <IMAGE>

Description

The invention relates to methods and devices for separating a bulk material flow into fractions with different grain sizes.

Bulk material flows with a wide grain band area must in many cases be separated into fractions with coarser grain band areas and fractions with finer grain band areas, whereby the fractions can be treated separately or one fraction can be treated separately and then combined again with the other fraction.

From US Pat. No. 3,356,213 a device for separating a bulk material stream consisting of iron ore pellets, coal, ash, lime and pellet fragments is known, which consists of an inclined chute with several shoulders and which has a gap between the last stage. When slipping down, the individual components of the bulk material flow on the slide experience an acceleration that depends on the respective frictional resistance, so that the throwing parabola of the material resulting from the speed at the end of the slide transports the pellets over the gap, while all other components fall into the gap. The material components are pre-separated at the individual stages. To improve the separation effect, several chutes can be connected in series, each with a gap. This device allows a satisfactory separation only for materials with very different shapes, grain sizes and properties and with a small amount of feed on the chute. In addition, the chute is heavily worn.

For this reason, screening devices are generally used to separate bulk material flows. One example is the crushing of sintered material after it has been thrown off the traveling grate and after it has been crushed in the spike crusher, whereby to relieve the roller crusher - the oversize is crushed to the desired size for use in the blast furnace - the undersize is screened beforehand and then the two fractions are combined again will. The sieves or grates of the sieving stations must be driven, have large sieve areas corresponding to the large quantities of material and are subject to heavy wear. This means that complex maintenance work is required and the service life of the system is limited.

The invention has for its object to provide a method and an apparatus which enables a separation of any bulk material flow in fractions of different grain size with the least possible equipment, wear and maintenance.

This object is achieved according to the invention in that, as a material broadener on a base with a convex, circular-arc-shaped discharge edge, a material cushion is propped up from the discharge edge at the angle of repose of the material, the surface of which forms a material-spreading surface, the throwing parabola of the freely falling bulk material flow onto the material-broadening Surface meets a saddle-shaped divider in the freely falling, widened material flow - consisting of a base with a convex-circular arc-shaped front discharge edge and a concave-circular-arc-shaped rear discharge edge and a material cushion bulging away from the discharge edges under the angle of repose of the material with a parallel to the discharge edges Comb - is arranged so that a coarser fraction on the front of the material cushion slides down to the convex discharge edge, is widened and thrown off, and that a finer fraction is applied the back of the material cushion slides down to the concave discharge edge and is thrown off.

• Von der gewünschten Abwurfbreite des gröberen Materialstroms von der vorderen Abwurfkante des Teilers ausgehend werden zwei Gerade an die Endpunkte des Auftreffbereiches des Materialstroms auf den Materialverbreiterer gezogen, und der Schnittpunkt der Geraden bildet den Mittelpunkt für den jeweiligen Kreisbogen aller Abwurfkanten. Der Schüttgutstrom kann von einem Förderband oder einer geneigten Schurre abgeworfen werden. Der horizontale Abstand des Materialverbreiterers von der Abwurfstelle des Schüttgutstromes und der horizontale Abstand des Teilers von dem Materialverbreiterer wird durch den gewünschten Entmischungszustand des Materials in der Wurfparabel des frei fallenden Materialstromes bestimmt.

The base of the material broadener consists of a sheet which can be arranged horizontally, partly horizontally and partly at an angle to the horizontal or entirely at an angle to the horizontal. If the angle to the horizontal is greater than the slope angle of the material, then a thin, upwardly protruding sheet metal strip must be arranged at the discharge edge, from the top edge of which the material cushion is exposed. This sheet metal strip is also preferably applied to a horizontal or slightly inclined base and serves to protect the edge of the base and to evenly form the material cushion. The convex arc-shaped discharge edge of the underlay lies at the front in the material's conveying direction. The expression "arcuate" includes an arc or a polygonal formation. The back of the material expander can be formed by a vertical wall that is attached to the base. The material broadener is arranged in the parabola of the material that is thrown off by a conveyor. An arcuate segment of a pouring cone is formed on the base by embossing the material on the base at the slope angle of the material starting from the discharge edge. The ridge of the pouring cone runs parallel to the discharge edge of the base in the width of the material stream that strikes it. The underlay is either made so wide that the material cushion that slopes away to the sides does not fall off, or a vertical wall is arranged on the underlay on each side. The surface of the pouring cone forms the material widening area. The stream of material falling on it is widened from the width of its impact point to the width of the discharge edge. As a result, the slipping material stream becomes thinner, the coarser pieces no longer float on the finer material, so that the different grain size fractions separate from the bulk material structure and develop their own mass and energy and acceleration. As a result, a greater segregation range is achieved in the discarded material flow. The stream of material thrown off by the material broader hits a saddle-shaped divider, which is arranged in the throwing parabola. In principle, this saddle-shaped divider is designed like the material widener. However, its backing also has a concave-circular rear discharge edge on the rear side. Due to the incoming material flow, an arcuate segment of a pouring cone is formed on the base by embossing the material from the front and rear discharge edge at the angle of the material. The cone crest runs parallel to the front and rear discharge edges. The divider is arranged in the throwing parabola of the material flow in such a way that a coarser fraction falls on the front of the pouring cone and a finer fraction on the rear side. The front side of the pouring cone acts as a material broadener and widens the coarser material flow to the width of the front discharge edge. The finer material flow sliding down on the rear side is narrowed to the width of the rear discharge edge. The respective radius of the discharge edge of the material widener and the front and rear discharge edge of the divider is set as follows:

• Starting from the desired discharge width of the coarser material flow from the front discharge edge of the divider, two straight lines are drawn to the end points of the impact area of the material flow on the material widener, and the intersection point of the straight line forms the center point for the respective circular arc of all discharge edges. The bulk material flow can be dropped from a conveyor belt or an inclined chute. The horizontal distance of the material broadener from the discharge point of the bulk material flow and the horizontal distance of the divider from the material broadener is determined by the desired separation state of the material in the parabola of the freely falling material stream.

A preferred embodiment is that the material broadening is designed as a saddle-shaped divider and the second saddle-shaped divider is arranged in the throwing parabola of the coarser fraction thrown off. As a result, a fine fraction is separated off as soon as the free-falling bulk material stream hits, the material stream sliding down on the front of the material cushion is correspondingly reduced and thinner, and thus the removal of the remaining grain size fractions from the bulk material stream is improved, and the separation when striking the second divider is also improved improved.

A preferred embodiment consists in the separation of the respectively coarser fraction on several saddle-shaped dividers arranged in a cascade. The number of saddle-shaped dividers depends on the requirements for the efficiency of the classification and depends on the ratio of fine to coarse material in the bulk material flow. A precisely defined fine fraction can be separated by several dividers. It is also possible to remove several fine fractions with different grain size bands separately.

A further solution to the problem is achieved in that a conical material cushion is erected as a material broadener on a circular base from the circular discharge edge at the angle of repose of the material, the surface of which forms a material broadening surface, the free-falling bulk material flow falling centrally onto the material cushion, freely falling, widened stream of material, a saddle-shaped divider - consisting of an annular base and a material pad with a circular comb that bulges up from the outer and inner circular discharge edge at the angle of repose of the material - is arranged in such a way that a coarser fraction on the outside of the material cushion to the outer discharge edge slides down, is widened and thrown off, and that a finer fraction on the inside of the material cushion slides down and is thrown off. The circular base of the material broadener consists of a sheet which can be arranged horizontally, partly horizontally and partly at an angle to the horizontal or entirely at an angle to the horizontal. If the angle to the horizontal is greater than the slope angle of the material, then a thin, upwardly protruding sheet metal strip must be arranged at the discharge edge, from the top edge of which the material cushion is exposed. This sheet metal strip is also preferably applied to a horizontal or slightly inclined base and serves to protect the edge of the base and to evenly form the material cushion. The freely falling bulk material flow falls centrally on the tip of the material cone or distributed around the tip on the material cushion. The circular base of the saddle-shaped divider is designed in accordance with the base of the material broadener det. The bulk material flow can be discharged, for example, from a bunker arranged above the material widener.

A preferred embodiment consists in the separation of the respectively coarser fraction from a finer fraction on several cascade-like, circular saddle-shaped dividers. The following saddle-shaped divider has a correspondingly larger diameter, so that it lies in the throwing parabola of the material from the previous divider. The dividers can be arranged to be vertically displaceable.

A device for solving the problem is characterized by a material widener (1), consisting of a base (2) with a convex-circular arc-shaped discharge edge (3) and a material cushion (4) erased from the discharge edge (3) at the angle of repose of the material on the Base (3) with a surface designed as a material widening surface (5), a discharge unit (6) arranged above the material widener (1), the parabola of which the free-falling bulk material (7) is directed towards the material widening surface (5), a saddle-shaped divider (8 ), which is arranged in the material stream (9) falling freely from the material broadener (1), consisting of a base (10) with a convex-circular arc-shaped front discharge edge (11) and a concave-circular arc-shaped rear discharge edge (12) and a bottom the angle of repose of the material from the throw-off edges (11, 12) bulging material pads (13) with e in a comb running parallel to the discharge edges (11, 12), and a derivative (15) for the coarser fraction and a derivative (16) for the finer fraction. The material widener and the saddle-shaped dividers are designed in accordance with the description of the method.

A preferred embodiment consists in that a saddle-shaped divider (8a) is arranged as the material widener, and the saddle-shaped divider (8) is arranged as a second divider under the throwing parabola of the coarser fraction (9) thrown off.

A preferred embodiment is that several saddle-shaped dividers (8a, 8, 8b, 8c) are arranged in a cascade.

A preferred embodiment is that the documents (2, 10-10c) are arranged to be horizontally displaceable.

Another device for solving the problem is characterized by a material widener (21) consisting of a circular base (22) with a circular discharge edge (23) and a conical material cushion (24) flared out from the discharge edge (23) at the angle of repose of the material on the Base (22) with a surface designed as a material widening surface (25), a feed device (26) from which the free-flowing bulk material stream (27) falls centrally onto the material cushion (25), a saddle-shaped divider (28) which is in the Material broadener (21) is arranged to drop freely, broadened material stream (29), consisting of an annular support (30) and a material cushion (33) flared out from the outer annular discharge edge (31) and the inner annular discharge edge (32) at the angle of repose of the material ) with a circular comb (34), and a drain (35) for the coarser fraction and a derivative (36) for the finer fraction.

A preferred embodiment consists in the fact that a plurality of circular saddle-shaped dividers (31, 31a) are arranged in cascade with one another.

A preferred embodiment consists in that the discharge edges (3, 11-11c, 12-12c, 23, 31, 31 a, 32, 32a) are formed by thin sheet metal strips (37) which are supported by the documents (2, 10a-10c , 22, 30, 30a) protrude.

A preferred embodiment consists in that contoured rods (38) are arranged on the bases (2, 10a-10c, 22, 30, 30a) of the surface of the material cushion (13-13c, 21, 33, 33a). The contour rods create a uniform material cushion with a precisely defined surface and throw-off edge.

• Fig. 1 ist ein Längsschnitt durch eine Trennvorrichtung.
• Fig. 2 ist ein Längsschitt durch einen Materialverbreiterer, der anstelle des ersten sattelförmigen Teilers in Fig. 1 eingesetzt werden kann.
• Fig. 3 ist eine Draufsicht von Fig. 1. Die vordere Kante des jeweiligen Teilers ist ausgezogen dargestellt, der Kamm des Materialpolsters ist strichpunktiert dargestellt und die hintere Kante ist gestrichelt dargestellt.
• Fig. 4 zeigt in Draufsicht die Ausbildung des Materialpolsters auf einem Teiler.
• Fig. 5 ist ein Längsschnitt durch eine Trennvorrichtung mit kreisringförmigen Teilern.
• Fig. 6 ist eine Draufsicht auf die Trennvorrichtung gemäß Fig. 5.
• Fig. 7 zeigt die Anordnung von Konturstäben auf einem Teiler.

The invention is illustrated by the figures.

• Fig. 1 is a longitudinal section through a separator.
• Fig. 2 is a longitudinal section through a material broadener that can be used in place of the first saddle-shaped divider in Fig. 1.
• FIG. 3 is a top view of FIG. 1. The front edge of the respective divider is shown in solid lines, the comb of the material cushion is shown in broken lines and the rear edge is shown in broken lines.
• Fig. 4 shows a top view of the formation of the material cushion on a divider.
• Fig. 5 is a longitudinal section through a separator with circular dividers.
• FIG. 6 is a top view of the separation device according to FIG. 5.
• Fig. 7 shows the arrangement of contour bars on a divider.

In Figures 1 and 2, five saddle-shaped dividers (8a, 8, 8b, 8c) are arranged in cascade in the housing (17). The saddle-shaped divider (8) consists of the base (10), with the convex-circular arc-shaped front discharge edge (11) and the concave-circular-arc-shaped rear discharge edge (12) and the flared material cushion (13). The material cushion (13) bends under the angle of repose of the material from the front chute (11) and the rear chute (12) and forms the ridge (14) which is parallel to the front (11) and rear (12) chute. The discharge edges (11 and 12) are formed by narrow metal strips (37) which are mounted vertically on the base (10). The saddle-shaped dividers (8a, 8b, 8c) are designed accordingly and analogously provided with position numbers. Chutes with material cushions (18, 18a, 18b) are arranged in the housing (17) at the points where dropped material hits the wall of the housing (17). The bulk material flow is thrown off the conveyor belt (6). The saddle-shaped divider (8a) is arranged in the throwing parabola of the freely falling bulk material flow (7) in such a way that the comb (14a) divides the bulk material flow into a finer and a coarser fraction. The finer fraction slips on the back of the material cushion to the discharge edge (12a), is thrown off by it and falls onto the material cushion (18). The coarser fraction slides on the front side of the material cushion (13a) to the discharge edge (11a) and is widened in the process. The next saddle-shaped divider (8) is arranged in the throwing parabola of the broadened material flow (9) falling freely from the discharge edge (11 a). The saddle-shaped divider (8) and the following saddle-shaped dividers (8b and 8c) act analogously to the first saddle-shaped divider (8a). The fine fractions thrown off by the saddle-shaped dividers (8a, 8 and 8b) are thrown off the chute (18) onto the chute (18a).

The finer fraction thrown off by the saddle-shaped divider (8c) also falls on the chute (18a). The combined finer fractions (16) are discarded and removed from the chute (18a). The coarser fraction thrown off by the saddle-shaped divider (18c) falls onto the chute (18b). The coarser fraction (15) is removed from the chute (18b).

As shown in Fig. 3, the center (19) for all radii of the circular discharge edges is determined by starting from the corner points of the desired discharge width of the coarser material flow from the last divider (11 c) two straight lines (20, 20a) to the end points the area of impact of the material flow onto the first divider (8a). The intersection (19) is the common center point for all arcuate discharge edges.

4, the end points of the front, concave-circular discharge edge (11a), the rear, convex-circular discharge edge (12a) and the comb (14a) of the material cushion (13a) running parallel to them are designated. The material widening area on which the coarser fraction slides down lies between the corner points (14a and 11a). The finer fraction slides down on the surface between the corner points (14a and 12a) and is narrowed in the process. In addition to this effective surface of the material cushion, the further course of the ineffective material cushion with its comb is shown on the right and left. This ineffective material cushion is not necessary for the method according to the invention. The effective material cushion could be delimited on the right and left by vertical walls and then the ineffective material cushion could be eliminated.

In FIGS. 5 and 6, the material broadener (21) consists of a circular base (22) on which a circular, thin sheet metal strip (37) is attached, the upper edge of which forms the discharge edge (23), and a conical material cushion (24) that picks up from the discharge edge (23) at the angle of repose of the material. The surface of the material cushion (24) forms the material widening surface (25). The saddle-shaped divider (28) is arranged under the material broadener (21) and consists of an annular base (30), on the inside and outside of which a thin circular sheet (37) is arranged, the upper edges of which are the outer annular discharge edge (31 ) and form the inner annular discharge edge (32), and a material cushion (33) which picks up from the discharge edges (31 and 32) at the angle of repose of the material and has a circular comb (34). The second annular divider (28a) is designed accordingly and provided with corresponding positions. A bulk material stream falls vertically from the bunker (26) centrally and around the tip of the conical material cushion (24). The flow of bulk material slides down on the material broadening surface (25) of the material cushion (24), is widened in the process and thrown off from the discharge edge (23). In the parabola of the thrown, widened bulk material flow (29), the annular divider (28) is arranged in such a way that a finer fraction slides down on the inside and is thrown off the discharge edge (32) and a coarser fraction slides down on the outside, thereby widening and is dropped from the discharge edge (31). The second annular divider (28a) is arranged accordingly. The finer fractions are collected and removed at (36). The coarser fraction is collected and discharged at (35).

The advantages of the invention are that bulk material flows can be separated into fractions of different grain sizes without moving parts, without energy expenditure and without wear, the device being able to be adapted to the required classification purity in a simple manner.

Claims (13)

1. A method for separating a flow of bulk material in fractions with different grain size, characterized in that as a material broadener on a base with a convex-circular discharge edge from the discharge edge under the angle of repose of the material a material cushion is erased, the surface of which forms a material broadening area, the throwing parabola of the free-falling bulk material flow meets the material widening area, in the freely falling, widened material flow a saddle-shaped divider - consisting of a base with a convex-circular arc-shaped front and a concave-circular-arc-shaped rear discharge edge and one that protrudes from the discharge edges at the angle of repose of the material Material upholstery with a comb running parallel to the discharge edges - is arranged so that a coarser fraction on the front of the material upholstery slides down, widens and falls off to the convex discharge edge is thrown, and that a finer fraction on the back of the material cushion slides down to the concave discharge edge and is thrown off. 2. The method according to claim 1, characterized in that the material broadening is designed as a saddle-shaped divider and the second saddle-shaped divider is arranged in the parabola of the thrown coarser fraction. 3. The method according to claim 1 or claim 2, characterized in that the separation of the respective coarser fraction takes place on several, cascade-like, saddle-shaped dividers. 4. A method for separating a bulk material flow into fractions with different grain size, characterized in that a conical material cushion is erased as a material broadener on a circular base from the circular discharge edge at the angle of repose of the material, the surface of which forms a material widening area, the freely falling bulk material flow A saddle-shaped divider - consisting of a circular base and a material cushion with a circular comb that bulges out from the outer and inner circular discharge edge at the angle of repose of the material - is arranged centrally on the material cushion in the freely falling, widened material flow so that a coarser fraction is arranged on the outside of the material cushion slides down to the outer discharge edge, is widened and thrown off, and that a finer fraction on the inside of the material cushion towards the inner A the edge of the throw slides down and is thrown off. 5. The method according to claim 4, characterized in that the separation of the respective coarser fraction from a finer fraction is carried out on several, cascade-like, saddle-shaped dividers. 6.Device for separating a bulk material flow into fractions with different grain sizes, characterized by a material broadener (1), consisting of a base (2) with a convex-arc-shaped discharge edge (3) and a flared at the angle of repose of the material from the discharge edge (3) Material cushion (4) on the base (3) with a surface designed as a material widening surface (5), a discharge unit (6) arranged above the material widener (1), the parabola of which the free-flowing bulk material flow (7) is directed towards the material widening surface (5) , a saddle-shaped divider (8), which is arranged in the widened metrial stream (9) falling freely from the material broadener (1), consisting of a base (10) with a convex-circular front breaking edge (11) and a knkav-circular rear breaking edge ( 12) and one under the angle of repose of the material from the throw-off ka nten (11, 12) bulging material pad (13) with a comb (14) running parallel to the discharge edges (11, 12), and a derivative (15) for the coarser fraction and a derivative (16) for the finer fraction. 7. The device according to claim 6, characterized in that a saddle-shaped divider (8a) is arranged as a material broadener, and the saddle-shaped divider (8) is arranged as a second divider under the throwing parabola of the coarser fraction thrown off (9). 8. Apparatus according to claim 5 or 6, characterized in that a plurality of saddle-shaped dividers (8a, 8, 8b, 8c) are arranged in a cascade. 9. Device according to one of claims 1 to 8, characterized in that the documents (2, 10-10c) are arranged horizontally displaceable. 10.Device for separating a bulk material flow into fractions with different grain sizes, characterized by a material broadener (21) consisting of a circular base (22) with a circular discharge edge (23) and a conical material cushion which is flared out from the discharge edge (23) at the angle of repose of the material (24) on the base (22) with a surface designed as a material widening surface (25), a feed device (26) from which the free-flowing bulk material stream (27) falls centrally onto the material cushion (25), a saddle-shaped divider (28), which is arranged in the widened stream of material (29) falling freely from the material broadener (21), consisting of an annular support (30) and a material cushion flared out from the outer annular discharge edge (31) and the inner annular discharge edge (32) at the angle of repose of the material (33) with a circular comb (34) and an A Lead (35) for the coarser fraction and a derivative (36) for the finer fraction. 11. The device according to claim 9, characterized in that a plurality of annular, saddle-shaped dividers (31, 31 a) are arranged in a cascade. 12. The method according to any one of claims 6 to 11, characterized in that the discharge edges (3, 11-11c, 12-12c, 23, 31, 31 a, 32, 32a) are formed by thin sheet metal strips (37) which over the documents (2, 10a-10c, 22, 30, 30a) protrude. 13. Device according to one of claims 6 to 12, characterized in that the supports (2, 10a-10c, 22, 30, 30a) of the surfaces of the material cushion (13-13c, 21, 33, 33a) matched contour rods (38) are arranged.

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